A system and method are disclosed for transporting deterministic traffic in a gigabit passive optical network. A system that incorporates teachings of the present disclosure may include, for example, an Optical Line Termination (OLT) for exchanging data traffic in a Gigabit passive Optical Network (GPON) having a controller programmed to generate a timeslot schedule for transport of a desired bandwidth of constant bit rate (CBR) data traffic by selecting one or more timeslots from periodic frame clusters operating according to a GPON Transmission Convergence (GTC) protocol. Additional embodiments are disclosed.
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18. A method for radio frequency identification tracking, comprising:
receiving first data by a gateway radio frequency identification tag from a first radio frequency identification reader, wherein the first data comprises a first response from a first group of passive radio frequency identification tags responding to a first radio frequency identification signal from the first radio frequency identification reader;
receiving second data by the gateway radio frequency identification tag from a second radio frequency identification reader, wherein the second data comprises a second response from a second group of passive radio frequency identification tags responding to a second radio frequency identification signal from the second radio frequency identification reader;
receiving a first request from the first radio frequency identification reader for the second data; and
transmitting the second data to the first radio frequency identification reader.
1. A method for radio frequency identification tracking, comprising:
transmitting a first radio frequency identification signal by a first radio frequency identification reader to a first group of passive radio frequency identification tags;
receiving at the first radio frequency identification reader first data from the first group of passive radio frequency identification tags in response to the first radio frequency identification signal;
transmitting the first data by the first radio frequency identification reader to a gateway radio frequency identification tag;
transmitting a query by the first radio frequency identification reader requesting second data from the gateway radio frequency identification tag, wherein the second data was previously transmitted to the gateway radio frequency identification tag by a second radio frequency identification reader; and
receiving the second data from the gateway radio frequency identification tag by the first radio frequency identification reader.
10. A radio frequency identification tracking system comprising:
a first passive radio frequency identification tag;
a gateway radio frequency identification tag;
a first radio frequency identification reader comprising:
a first radio frequency transmitter for transmitting a first radio frequency signal to the first passive radio frequency identification tag;
a first radio frequency receiver for receiving first tag data from the first passive radio frequency identification tag in response to the first radio frequency signal; and
wherein the first radio frequency transmitter for transmitting the first tag data from the first passive radio frequency identification tag to the gateway radio frequency identification tag, and for transmitting a first query from the first radio frequency identification reader to the gateway radio frequency identification tag, wherein the first query comprises a first request for second data from the gateway radio frequency identification tag, wherein the second data was previously transmitted to the gateway radio frequency identification tag by a second radio frequency identification reader.
2. The method of
3. The method of
4. The method of
5. The method of
6. The method of
8. The method of
9. The method of
11. The radio frequency identification tracking system of
a second passive radio frequency identification tag;
the second radio frequency identification reader comprising:
a second radio frequency transmitter for transmitting a second radio frequency signal to the second passive radio frequency identification tag;
a second radio frequency receiver for receiving second tag data from the second passive radio frequency identification tag in response to the second radio frequency signal; and
wherein the second radio frequency transmitter for transmitting the second tag data from the second passive radio frequency identification tag to the gateway radio frequency identification tag, and for transmitting a second query from the second radio frequency identification reader to the gateway radio frequency identification tag, wherein the second query comprises a second request for the first tag data from the gateway radio frequency identification tag.
12. The radio frequency identification tracking system of
a third radio frequency receiver for receiving the first tag data, second tag data, the first query, and the second query from the first radio frequency identification reader and the second radio frequency identification reader;
a memory for storing the first tag data from the first radio frequency identification reader and the second tag data from the second radio frequency identification reader; and
a third radio frequency transmitter for transmitting to the first radio frequency identification reader, in response to the first query from the first radio frequency identification reader, the second tag data received from the second radio frequency identification reader, and transmitting to the second radio frequency identification reader, in response to the second query from the second radio frequency identification reader, the first tag data received from the first radio frequency identification reader.
13. The radio frequency identification tracking system of
a central database connected to the gateway radio frequency identification tag via a network.
14. The radio frequency identification tracking system of
15. The radio frequency identification tracking system of
16. The radio frequency identification tracking system of
17. The radio frequency identification tracking system of
19. The method of
receiving a second request from the second radio frequency identification reader for the first data; and
transmitting the first data to the second radio frequency identification reader.
20. The method of
transmitting by gateway radio frequency identification tag the first data and the second data to a central database.
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This application is a continuation of U.S. Ser. No. 11/999,398, filed Dec. 5, 2007now U.S. Pat. No. 7,902,985, which is currently allowed and is herein incorporated by reference in its entirety.
This invention relates to a radio frequency identification (RFID) systems that use RFID tags to track product inventory, or other mobile items.
Information management systems are being developed to track the location and/or status of a large variety of mobile entities such as products, vehicles, people, animals, etc. A widely used tracking technology uses so-called RFID tags that are placed physically on the items being tracked. Reference herein to “items” being tracked is intended to include the variety of entities just mentioned as well as, more commonly, product inventories.
RFID tags may be active or passive. Active tags typically have associated power systems and can transmit data over modest distances. Passive systems lack internal power but derive transmitting signal power from an incoming RF signal. However, transmitting distances with passive RFID tags are very limited. To read a large number of RFID tags, spread over a wide physical area, requires either a large number of RFID readers, or a reliable system of moving RFID readers. One proposed solution to this problem is to use active RFID tags on the products. However, active tags are relatively costly. Although they lend more function to a tracking system, and transmit more effectively, passive tags are typically more cost effective where inventories being tracked are large.
What is needed is an improved system for RFID tracking where the scale of the application exceeds the performance capability of conventional RFID approaches.
We have developed a new architecture for RFID systems that is adapted to process large numbers of RFID tags and provide information about a large number of items. The system provides for multiple tag readers. The tag readers are active and have both transmit and receive capability. The system includes a new element called a gateway tag that receives information about individual items from the multiple readers and thus contains data on the entire inventory of items. This allows each of the multiple readers to access data for the entire inventory of items. The gateway tag may interface with an information storage center that also contains data for the entire inventory of items.
The invention may be better understood when considered in conjunction with the drawing in which:
A passive RFID tag is shown at 21 in
Passive RFID tag designs are available in many sizes and designs. Common characteristics are a platform, an IC chip, and an antenna. Depending on the application the platform may be glass, ceramic, epoxy, paper, cardboard, or any suitable plastic. An onboard power source is not included in a passive RFID tag. All power for the tag is derived from RF signals in the vicinity of the tag. The tag responds to the reader using RF backscatter, which basically reflects the carrier wave from the reader after encoding data on the carrier wave. Variables in the communication specification include the frequency of the carrier, the bit data rate, the method of encoding and any other parameters that may be needed. ISO 18000 and EPCGlobal are the standards for this interface. The interface may also include an anti-collision protocol that allows more than one tag in the range of the reader to signal concurrently. There are many specific implementations of this, and these form no part of the invention.
A typical schematic for an RFID reader is shown in
A schematic of an RFID tag system according to the invention is shown in
A schematic of the gateway RFID tag 45 in
For the purpose of defining terms used herein, a passive RFID tag means a device containing at least an integrated circuit chip operating at a given frequency and an antenna, but no onboard power source. The antenna operates as a low power RF transceiver. The integrated circuit chip contains a memory. An RFID reader means a device containing at least an integrated circuit chip, an antenna, an RF transmitter, an RF receiver, and a power source. The integrated circuit chip in the RFID reader contains a memory. The RFID reader has an RF transmitter that operates at the same frequency as the RFID tags, and an RF transmitter that may operate at a frequency different from that of the RFID tags. A gateway RFID tag means a device containing at least an integrated circuit chip, an antenna, an RF transmitter, an RF receiver, and a power source. The integrated circuit chip in the gateway RFID reader contains a memory. The gateway RFID reader has an RF transmitter that operates at the same frequency as the RFID readers, and may have a communications link to a remote central database. A remote central database has a microprocessor and a memory store. It may or may not be located on the same physical premises as the gateway RFID tag.
Transmitting range means the range over which signals transmitted from a transmitting device can be received by a receiving device.
In summary, an aspect of the invention is that data from an item that is not in the vicinity of an RFID reader, and thus not accessible directly from that reader, can nevertheless be accessed by that reader through the gateway RFID tag. The sequence of operations for accomplishing this involves transmitting an RFID signal between a first RFID reader and a first group of passive RFID tags, receiving at the first RFID reader first data from the first group of passive RFID tags, transmitting said first data from the RFID reader to a gateway RFID tag, receiving and storing the first data at the gateway RFID tag, transmitting an RFID signal between a second RFID reader and a second group of passive RFID tags, receiving at the second RFID reader second data from the second group of passive RFID tags, transmitting said second data from the RFID reader to the gateway RFID tag, receiving and storing the second data at the gateway RFID tag, transmitting to the gateway RFID tag a query from the first RFID reader, receiving the query at the gateway RFID tag, and transmitting second data from the gateway RFID tag to the first RFID reader.
Various additional modifications of this invention will occur to those skilled in the art. All deviations from the specific teachings of this specification that basically rely on the principles and their equivalents through which the art has been advanced are properly considered within the scope of the invention as described and claimed.
Rice, Christopher, Killian, Thomas
Patent | Priority | Assignee | Title |
11213773, | Mar 06 2017 | Cummins Filtration IP, Inc | Genuine filter recognition with filter monitoring system |
8581729, | Dec 05 2007 | AT&T Intellectual Property II, L.P. | Gateway radio frequency identification tag system |
Patent | Priority | Assignee | Title |
7068148, | Oct 18 2002 | Symbol Technologies, LLC | Method for the efficient reading of a population of radio frequency identification tags with unique identification numbers over a noisy air channel |
7295108, | Mar 22 2004 | EDGY COMMUNICATIONS, LLC | Active RFID tag utilizing a secondary communication mode |
7573386, | Aug 19 2004 | KYNDRYL, INC | System and method for smart radio frequency identification tags |
7633392, | May 05 2004 | General Electric Company | Radio frequency identification asset management system, and computer program product |
7902985, | Dec 05 2007 | AT&T Intellectual Property II, L.P. | Gateway radio frequency identification tag system |
20060145815, | |||
20080297312, | |||
20090021343, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Nov 29 2007 | KILLIAN, THOMAS | AT&T Corp | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 025914 | /0369 | |
Dec 04 2007 | RICE, CHRISTOPHER | AT&T Corp | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 025914 | /0369 | |
Mar 07 2011 | AT&T Intellectual Property II, L.P. | (assignment on the face of the patent) | / |
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